BACnet Communication Interface (BCI-I)

Transcription

Integration Guide
BACnet™ Communication
Interface (BCI-I)
for IntelliPak™ and Commercial Self-contained
September 2009
ACC-SVP01B-EN
Copyright
© 2009 Trane All rights reserved
This document and the information in it are the property of Trane and may not be used or reproduced in whole
or in part, without the written permission of Trane. Trane reserves the right to revise this publication at any
time and to make changes to its content without obligation to notify any person of such revision or change.
Trademarks
IntelliPak, Tracer, Trane, and the Trane logo are trademarks of Trane in the United States and other countries.
All trademarks referenced in this document are the trademarks of their respective owners.
2
ACC-SVP01B-EN • BCI0I Integration Guide
Table of Contents
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
Ordering Numbers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
BACnet Protocol . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
BCI-I Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
Starting a Session of Tracer TU and Direct Connection . . . . . . . . . . . . . . . . . 5
IP Units Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
BACnet Object Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
Change Baud Rate . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
Change Device ID . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7
Stand-alone or BAS Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
IntelliPak Control Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
BAS Unit Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Periodic Update of BAS Values . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
BAS Communication Failure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
8
8
9
9
Input/Output Commands and Calculations . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
System Control Command . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
Filter Timer Reset Command . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
Diagnostics Reset Command . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
Setpoint Calculations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
Timestamp Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
BCI IntelliPak Rotary Switches and LEDs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
Rotary Switches . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
LEDs Description, Behavior, and Troubleshooting . . . . . . . . . . . . . . . . . . . . . 13
BACnet Data Points and Configuration Property Definitions . . . . . . . . . . . . . . . 17
BACnet Protocol Implementation Conformance Statement (PICS) . . . . . . . 17
Standardized Device Profile (Annex L) . . . . . . . . . . . . . . . . . . . . . . . . . . .
Interoperability Building Blocks (Annex K) . . . . . . . . . . . . . . . . . . . . . . . .
Segmentation Capability . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Object Types . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
17
17
18
19
BACnet Protocol . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
Data Link Layer Options . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
Device Address Binding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
Networking Options . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
Object Data Points and Diagnostic Data Points . . . . . . . . . . . . . . . . . . . . . . . . . . . 24
Additional Resources . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44
Glossary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45
ACC-SVP01B-EN • BCI-I Integration Guide
3
Overview
The BACnet Communication Interface for IntelliPak (BCI-I) is comprised of a Tracer™ UC400
controller with interface software. It is a non-programmable communications module that allows
heating, ventilation, and air-conditioning (HVAC) equipment to communicate on a BACnet
communications network.
This guide provides:
•
A list of ordering numbers
•
A brief overview of the BACnet™ protocol
•
BCI-I configuration information
•
A explanation of the BCI-I device rotary switches and LEDs
•
Data point configuration property definitions
•
Tables listing object data points
•
Additional resources
•
A glossary of terms
Note: Users of this guide should have basic knowledge of BACnet protocol. For more detailed
information about this protocol, visit the company web site listed under “Additional
Resources,” p. 44.
Ordering Numbers
Order Number
Description
X13651544-010
IntelliPak I; for software and hardware
C175218460010
IntelliPak I, II, and CSC; for field-installed kit
BACnet Protocol
The Building Automation and Control Network (BACnet and ANSI/ASHRAE Standard 135-2004)
protocol is a standard that allows building automation systems or components from different
manufacturers to share information and control functions. BACnet provides building owners the
capability to connect various types of building control systems or subsystems together for a variety
of reasons. In addition, multiple vendors can use this protocol to share information for monitoring
and supervisory control between systems and devices in a multi-vendor interconnected system.
The BACnet protocol identifies standard objects (data points) called BACnet objects. Each object
has a defined list of properties that provide information about that object. BACnet also defines a
number of standard application services that are used to access data and manipulate these objects
and provides a client/server communication between devices. For more information on BACnet
protocol, refer to “Additional Resources,” p. 44.
BACnet Testing Laboratory (BTL) Certification
The BCI-I supports the BACnet communication protocol and has been designed to meet the
requirements of the application-specific control profile. For more details, refer to the BTL web site
at www.bacnetassociation.org.
4
BCI-I Configuration
BCI-I Configuration
This section will provide the following information when configuring the BCI-I:
•
Overview
•
Starting a session of Tracer TU and direct connection
•
Resetting to factory default
•
Configuring IP units
•
Configuring BACnet objects
•
Changing baud rate and device ID
•
Input/output and equipment functions
Overview
The BCI-I device is designed as a self-configuring controller to accommodate the many possible
equipment configuration options available in the IntelliPak line of equipment. This self-configuring
device eliminates the need for the BAS technician having to create BACnet objects, minimizes the
risk of object configuration errors, and allows the IntelliPak unit to be quickly installed in the BAS.
The self-configuration process only creates objects that are appropriate for the feature set of the
specific IntelliPak unit the BCI-I is connected to. Once this process is complete, the device exits
factory mode and enters the normal mode of operation. At this point, the self-configuration process
will not start when power is applied to the device.
The set of objects listed in Table 3, p. 24 through Table 10, p. 31, are the super set of all possible
objects supported by the IntelliPak line of equipment. The BAS technician should query the device
for the list of actual objects that have been created in the device.
Starting a Session of Tracer TU and Direct Connection
Tracer TU is the service tool software that allows the technician to modify the operation of the
device and to discover the BACnet objects present in the device. To modify the device or discover
objects, the user must first connect to Tracer TU as follows:
WARNING: Remove power from the HVAC equipment before opening
electrical control panel.
1. Connect a USB cable directly between the laptop PC and the service port located on the front
of the BCI-I device. When connecting to the controller for the first time, the Found New
Hardware Wizard appears. Follow the wizard instructions to install the USB hardware driver.
2. Click either the Tracer TU desktop icon or the Tracer TU program item in the Tracer TU group
on the Start menu. The Tracer TU splash screen appears briefly followed by the Connect
dialog box.
3. Select the Direct Connection (Via USB cable) radio button if it is not already selected.
4. Click the Connect button and the Tracer TU main page will appear after successful connection.
Note: The BCI-I may be powered via the USB cable or 24 Vac from the HVAC unit. Concurrent
connection of unit power and the USB cable will not harm the BCI-I device.
For more detailed information about direct connection to Tracer TU, refer to the Tracer™ TU Service
Tool Getting Started Guide (TTU-SVN02) (X39641083).
5
BCI-I Configuration
Reset to Factory Default
Factory default mode is the only mode the technician can use to set the units of measure for the
device or to scan the IntelliPak unit to create BACnet objects. The process of putting the device in
factory default mode must be run prior to executing units of measure configuration or the object
self-configuration process.
WARNING: Remove power from the HVAC equipment before
opening electrical control panel.
To reset the controller to factory default/unconfigured state:
1. Power down the unit. The IMC buss must not be active during reset.
2. Establish the connection between Tracer TU and the device. Follow the procedure, “Starting a
Session of Tracer TU and Direct Connection,” p. 5.
3. From the Utilities menu, select Controller and then Controller Settings. The Controller
Settings page appears.
4. On the controller settings page there is a gray bar at the bottom with Save/Cancel buttons.
Move the cursor near the left edge of the bar, keeping the cursor inside the bar. Click on this area
and a Clear Controller button will appear in the upper right portion of the page.
5. Click the Clear Controller button and a pop-up window will appear asking for confirmation to
reset the device. Click Yes.
6. After a few seconds a pop-up will appear confirming that the controller has been reset and
indicating that the controller will be rebooted. Click OK.
After the controller boots up, it will be in factory default state. The units of measure is SI (metric),
the MS/TP baud rate is 76,800, and there will be no BACnet objects present in the controller.
The controller must be in this state prior to changing the units of measure or self-configuring
the device. If using inch-pound units of measure, proceed to the next section, “IP Units
Configuration, otherwise, proceed to “BACnet Object Configuration.
IP Units Configuration
The BCI-I supports both inch-pound and SI (metric) units of measure. The factory default units of
measure is SI. The device allows only a change of units for all objects as a whole. Mixed units of
measure is not allowed. If the controller is not in factory default state, follow the previous
procedure, “Reset to Factory Default,” p. 6.
To change the units of measure in the device:
1. Establish the connection between Tracer TU and the BCI-I. Follow the procedure,“Starting a
2. From the Utilities drop-down menu, select Controller and then Controller Settings. The
page contains four configuration frames that are minimized. Expand the Controller Units
frame.
3. In the Device Units box of the frame, select IP units of measure radio button and then click
Save button in the lower right corner of the window. A pop-up will display indicating that
changes were saved to the controller. Select OK.
4. Exit Tracer TU and cycle power to the controller by disconnecting the USB plug and then
reconnecting the plug. After the controller boots up, it will be in factory default state, the units
of measure is IP, the MS/TP baud rate is 76,800, and there will be no BACnet objects present in
the controller.
6
BCI-I Configuration
BACnet Object Configuration
Configuring BACnet objects is a self-configuring process. If the controller is not in factory default
state, follow the previous procedure, “Reset to Factory Default,” p. 6.
1. Remove the USB cable plug from the device.
2. Apply power to the HVAC equipment. After the device boots up, the self-configuration process
will begin. No further user action is required.
Note: Do not remove power while the device is in self-configuration mode. This typically takes
2 to 4 minutes to complete. Once complete, the device enters normal operating mode.
Change Baud Rate
The BCI-I device supports four baud rates: 9600, 19200, 38400, and 76800 baud. The default baud
rate is 76800 baud. The baud rate can be modified with Tracer TU.
To change baud rate:
page contains four configuration frames that are minimized. Expand the Protocol frame.
3. Click on the drop down arrow for the Baud Rate list and select the desired baud rate.
4. Click Save button in the lower right corner of the window. A pop-up will display indicating that
changes were saved to the controller. Click OK.
5. Exit Tracer TU and disconnect the USB cable plug.
6. Apply power to the HVAC equipment.
Change Device ID
By default, the BCI-I device sets its device ID to the same value as the one defined by the rotary
switches (MS/TP MAC address) on the front of the device. Refer to the section, “Rotary Switches,”
p. 12. For simple networks, this is an easy method to guarantee unique device IDs across the link.
The device also supports the full range of device ID values as specified by the BACnet Standard.
Systems that require a more complex device ID convention are supported with Tracer TU, which
has the ability to set the device ID via software configuration.
The process for soft setting the device ID is as follows:
page contains four configuration frames that are minimized. Expand the Protocol frame.
3. In the device ID box, select the check box next to Use Software Device ID to enable the
functionality. The swipe-and-type box becomes available.
4. Type in the desired device ID.
7
BCI-I Configuration
5. Click the Save button in the lower right corner of the window. A pop-up will display indicating
that changes were saved to the controller. Click OK.
6. Exit Tracer TU and disconnect the USB service plug.
7.
Apply power to the HVAC equipment.
Stand-alone or BAS Operation
The control system on HVAC equipment has the ability to operate the unit as a stand-alone system
or as part of a building automation system. The BCI-I (either factory or field installed), by default,
is configured for stand-alone operation. This configuration enables the HVAC equipment to operate
prior to the commissioning of the unit into the BAS.
IntelliPak Control Configuration
The IntelliPak control system must be configured at the human interface (HI) to support unit control
from the BAS. The technician should set/verify the following configuration properties as illustrated
below. The technician should also verify that the BAS Module Comm Failure diagnostic is not
present.
1.
Configuration Menu
Configuration - Model Num Digit
BAS Communication Module
34
Installed
Software Revision Number:
BAS Communications:
BACnet
18.01
Human Interface Representation
2.
Setup Menu
Unit Control: BAS/NETWORK
3.
Diagnostics Menu
Active Diagnostic - - Auto Reset
None
BAS Unit Control
The BCI-I provides a method for a BAS to control the operation of HVAC equipment. This method
consists of BACnet objects that the BAS can access to control and monitor the status of equipment.
There are two sets of objects:
•
Output objects; used by the BAS to provide command, setpoint, and sensor information to the
IntelliPak unit.
•
Input objects; provide IntelliPak status information to the BAS. See tables 3 to 11 for the list of
objects supported.
The system allows the BAS technician to define the amount of control that the BAS system will
apply to the unit. This is done by configuring the state of the Out of Service property of the output
objects. If the property is set to True, the equipment will use a corresponding local value for control.
If the property is set to False, the local value is ignored and the BAS-supplied value is used for
control. The BAS value is provided to the IntelliPak by writing to the present value property of the
corresponding output object. The factory default value for the Out of Service property of these
objects is True.
8
BCI-I Configuration
Periodic Update of BAS Values
The BCI-I device requires the BAS system to provide a periodic update to the sensor values. This
is required to protect against a loss of communication between the BAS and the BCI-I. By BACnet
definition, the present value of the object will maintain the last value written to it, regardless of the
amount of time that has elapsed since the last write. If communication is lost for several minutes
or longer, the present value of BAS-supplied sensor objects may no longer represent the current
state of environmental conditions. This may result in decreased occupant comfort and damage to
building systems.
BAS Communication Failure
The BCI-I is designed to minimize communication failure mode. It does this by monitoring the
length of time that has elapsed since the last write to the present value of the sensor object. If the
length of time exceeds a predefined limit, the BCI-I will place the object into the fault state and revert
to a unit-supplied sensor value for control. At power up, the sensor objects are set to a fault state
and they will remain in this state until a write is detected. The minimum periodic refresh rate for
the objects is defined in Table 3, p. 24. The following list is a set of sensor values that can be
supplied by the BAS:
•
Space Static Pressure BAS
•
Space Air Temperature BAS
•
Discharge Air Temperature BAS
•
Duct Static Air Pressure BAS
•
Outdoor Air Temperature BAS
•
Outdoor Air Humidity BAS
•
Outdoor Airflow BAS
•
Space CO2 Concentration BAS
•
Space Humidity BAS
Input/Output Commands and Calculations
This section will provide the following information about certain inputs and outputs that perform
unique control commands and calculations:
•
System control command
•
Filter timer and diagnostic reset commands
•
Setpoint calculations
System Control Command
Binary Output Object 1, has a special importance in the system. The object allows the BAS to
command the unit to run in a local or BAS control mode. When the present value property of the
object is set to Local Control, the IntelliPak unit will enter local control and ignore BAS supplied
values. In this mode, the unit will use local sensor and setpoint values. When the object present
value property is set to BAS Control, the IntelliPak unit will use the values supplied by the BAS
system for unit control.
Filter Timer Reset Command
The BCI-I uses the Filter Runtime Hours object (AI 6) to generate a diagnostic when its present value
is greater than the Filter Runtime Hours Setpoint, (AV 1) present value. The procedure for resetting
the timer is as follows:
9
BCI-I Configuration
The BAS will change the state of the Filter Timer Reset Command object (BO 13) to the active
state. Upon the change to active state, the BCI-I will set the present value of the Filter Runtime
Hours object to zero and then set the Reset Command object back to the inactive state.
Diagnostics Reset Command
The IntelliPak control system monitors the operation of the HVAC equipment. If an abnormal
condition is detected, a diagnostic message is displayed on the human interface of the equipment
control panel. In addition, the set of internal diagnostics is mapped to the set of BACnet binary input
objects, as listed in Table 9, p. 31. The corresponding BI object will change state from inactive to
active when the diagnostic is detected. The object has been configured to send a BACnet event
message to external BACnet devices as defined by the protocol.
The BAS has the ability to reset internal diagnostics by controlling the state of the Diagnostic Reset
Command object (BO 14). The procedure for resetting diagnostics is as follows:
The BAS will change the state of the Diagnostic Reset to the active state. Upon the change to
active state, the IntelliPak control system will reset all internal diagnostics and set the state of
all of the diagnostic objects to inactive. Upon completion of this action, the BCI-I will set the
present value of the Diagnostic Reset Command object back to the inactive state.
Setpoint Calculations
The equipment has the ability to perform two basic control functions:
•
Space air temperature control
•
Discharge air temperature control
When the unit is configured for discharge air control, it controls the temperature of the air leaving
the unit to the discharge air temperature setpoint.
When the unit is configured for space air temperature control, it controls the air temperature of the
space that contains the space air temperature sensor. This value may be provided by wiring the
sensor to the unit or via a sensor value provided by the BAS.
The drawing below describes how the various temperature setpoints are calculated for space
temperature control. When the unit is in an occupied mode the active space temperature setpoint
is calculated based on the space temperature setpoint and the two setpoint offset values. In
unoccupied mode, the unoccupied heating and cooling setpoints are used as the active setpoint.
10
BCI-I Configuration
Timestamp Configuration
The BCI-C device has a software-derived clock that maintains the time and date. The device requires
the current time to enable it to record a timestamp when an event or a change in state is detected
by a BACnet object. However, in the event of a power loss, the device does not maintain this time
and date information. At powerup, the device time and date will default to 12:00 pm., Jan 1, 1970.
To minimize the possibility that the unit timestamp is not representing the actual time, the BAS
should be setup to periodically synchronize the device time clock with the BAS clock using the
BACnet TimeSynchronization service.
11
BCI IntelliPak Rotary Switches and LEDs
This section provides information about the BCI-I rotary switches and LED displays.
Rotary Switches
There are three rotary switches on the front of the BCI-I device that are used to define a three-digit
address when the BCI-I is installed on a BACnet communications network. The three-digit address
setting is the BACnet MAC address.
Note: All devices are MSTP masters with valid MAC addresses of 001 to 127 for BACnet.
Figure 1.
Setting rotary switches
Before
After
ADDRESS
90 1
7 8
7 8
90 1
2 3
2 3
2 3
7 8
90 1
4 56
4 56
4 56
x100
x10
x1
Example of before and
after setting addresses
Each device on the BACnet/MSTP link must have a unique rotary switch setting, otherwise, communication problems will occur.
12
78
901
23
Use a 1/8 inch
flathead screwdriver
to set rotary switches.
456
Important:
LEDs Description, Behavior, and Troubleshooting
There are 15 LEDs on the front of the BCI-I unit. However, LEDs BO1 through BO9 are not used for
the BCI-I controller. Figure 2 shows the locations of each LED. The following table provides a
description of each LED activity, an indication or troubleshooting tips for each, and any notes.
Figure 2.
LED locations
Marquee LED
LINK IMC
TX
RX
SERVICE
Table 1.
LED Activities and Troubleshooting Tips
LED Name
Activities
Shows solid green when the unit is
powered and no problems exist
Marquee LED
Indication or Troubleshooting
Tip (Denoted in Bullets)
Shows solid red when the unit is
powered, but represents low power or a
malfunction
• If low power; could be under voltage
or the microprocessor has
malfunction. Follow the troubleshoot
procedure “24 Vac Measurement,”
p. 15 to measure for the expected
value range.
• If malfunction; unpower and then
repower unit to bring the device back
up to normal operation.
Shows blinking red when an a BACnet
object is in a fault condition
Alarm; when an alarm is triggered, for
example, when a point goes into fault
condition because of point failure or
there is an indication of a custom alarm
in TGP2
Shows blinking green when the device
does not detect the IMC buss
• Verify that the IPC wiring harness is
connected to the IMC link terminals.
• Verify the polarity of the IPC wiring
harness at the unit terminals.
LED not lit
Notes
Indicates normal operation
Indicates power is OFF or there is a
malfunction
• OFF or malfunction; cycle the power.
13
Table 1.
LED Activities and Troubleshooting Tips
LED Name
Activities
TX blinks green
Link and IMC
RX blinks yellow
Blinks at the data transfer rate when the
unit transfers data to other devices on
the link
Blinks at the data transfer rate when the
unit receives data from other devices on
the link
Shows solid green
Blinks green
Notes
TX LED: Regardless of connectivity or
not, this LED will constantly blink as it
continually looks for devices to
communicate to.
Indicates that the controller is not
detecting communication
LED not lit:
Determine if, for example, a Tracer SC or
BACnet device is trying to talk to the
controller or if it is capable of talking to
the controller. Also determine if the
communication status shows down all of
the time.
• Not lit; cycle the power to reestablish
communication
Refer to “Ground Measurements,” p. 16
for a check-out procedure.
Indicates someone is pressing this LED
or the controller is not operating
normally
Press and hold during power up to place
controller into boot code or press and
hold for a count of approximately 10
seconds to clear the Device ID.
• ON solid yellow; indicates there is
reverse polarity
LED not lit
Service
Indication or Troubleshooting
Tip (Denoted in Bullets)
Indicates controllers is not accessing
application software
What is Boot Code? When the UC400
is placed into boot code, the system
will not run any applications such as
Indicates controller is operating normally trending, scheduling, and TGP2
runtime.
• Restore; using TU service tool
LED not lit
Binary 01 to Binary 09
14
Not Used
24 Vac Measurement
General Information
Checkout Procedure
Checking the voltage that is
powering the UC400 is often a
Step 1
necessary step when commissioning
or troubleshooting. Operational
issues and LED operation may result
in a need to measure the input
power.
When troubleshooting, it is faster to
take measurements while the load is
in place. If Step 1 indicates an outof-specification voltage, disconnect Step 2
the UC400 and measure the AC
voltage across the transformer.
These measurements can direct the
technician towards the problem
source.
Measurement
Expected Value
Measure AC voltage with the
UC400 connected. Perform this
measurement while the unit is
under load.
20.0 Vac ≤ Vac ≤ 30.0 Vac
Measure AC voltage with the
UC400 unconnected. Perform this
measurement while the unit is not
under load.
20.0 Vac ≤ Vac ≤ 30.0 Vac
15
Ground Measurements
General Information and Checkout Procedure
Measurement
Expected Value
Method 1:
AC voltage between shield conductors and device chassis groundthe voltage difference between BACnet MS/TP device chassis ground
connections should be close to zero. If the voltage difference is greater that
4.0 Vac, there will be marginal communication or intermittent
communication problems. If the voltage difference is greater that 7.0 Vac,
some devices will no longer communicate.
Measure AC current
across the current
termination and confirm
that only one end of the
shield conductor is tied to
the earth ground
Vac ≤ 2.0 V
Method 2:
AC voltage between earth ground and device chassis ground- the
chassis ground of the UC400 needs to be connected to earth ground by
some route.
Measure AC current
across the current
termination and confirm
that only one end of the
shield conductor is tied to
the earth ground
Vac ≤ 4.0 V
(Must comply with National Electrical
Code™and local electrical codes)
Note:
16
Do not assume that the building frame is a valid earth ground.
BACnet Data Points and Configuration Property Definitions
BACnet Data Points and Configuration Property
Definitions
The BCI device allows an IntelliPak control system to communicate with BACnet systems and
devices using BACnet MS/TP. This section includes information about:
•
BACnet protocol implementation conformance statement (PICS)
•
Object types: descriptions and configuration (refer to Table 2, p. 19)
•
BACnet protocol: data link layers, device address binding, networking options, and character
sets
•
Object data points and configurations
BACnet Protocol Implementation Conformance Statement (PICS)
Standardized Device Profile (Annex L)
Profile Description
Supported Profile
BACnet Advanced Application Controller (B-AAC)
BACnet Application Specific Controller (B-ASC)
9
BACnet Building Controller (B-BC)
BACnet Operator Workstation (B-OWS)
BACnet Smart Actuator (B-SA)
BACnet Smart Sensor (B-SS)
Interoperability Building Blocks (Annex K)
Data Sharing Description
Supported BIBB
Data Sharing-COV-B (DS-COV-B)
Data Sharing-ReadProperty-A (DS-RP-A)
9
Data Sharing-ReadProperty-B (DS-RP-B)
9
Data Sharing-ReadPropertyMultiple-B (DS-RPM-B)
9
Data Sharing-WriteProperty-A (DS-WP-A)
9
Data Sharing-WriteProperty-B (DS-WP-B)
9
Data Sharing-WritePropertyMultiple-B (DS-WPM-B)
9
Alarm and Event Management Description
Supported BIBB
Alarm and Event-ACKI-B (AE-ACK-B)
9
Alarm and Event-Alarm Summary-B (AE-ASUM-B)
9
Alarm and Event-Enrollment Summary-B (AE-ESUM-B)
9
Alarm and Event-Information-B (AE-INFO-B)
9
Alarm and Event-Notification Internal-B (AE-N-I-B)
9
17
Trending Description
Supported BIBB
Trending-Automated Trend Retrieval-B (T-ATR-B)
9
Trending-viewing and Modifying Trends Internal-B (T-VMT-I-B)
9
Device Management Description
Supported BIBB
Device Management-Backup and Restore-B (DM-BR-B)
9
Device Management-Device Communication Control-B (DM-DCC-B)
9
Device Management-Dynamic Device Binding-A (DM-DDB-A)
9
Device Management-Dynamic Device Binding-B (DM-DDB-B)
9
Device Management-Dynamic Object Binding-B (DM-DOB-B)
9
Device Management-List Manipulation-B (DM-LM-B)
9
Device Management-Object Creation and Deletion-B (DM-OCD-B)
9
Device Management-Private Transfer-A (DM-PT-A)
9
Device Management-Private Transfer-B (DM-PT-B)
9
Device Management-Reinitialize Device-B (DM-RD-B)
9
Device Management-TimeSynchronization-B (DM-TS-B)
9
Segmentation Capability
Segmentation Description
Segmented Requests/ Window Size: 1
Segmented Responses/ Window Size: 1
18
Supported Segment
9
9
Object Types
Table 2.
Object
Type
Descriptions and configurations
Ability
to
Create
Ability to
Delete
Required Properties Read
Properties Written(a)
Optional Properties Read
Analog
Input
•
•
•
•
•
•
•
•
Object_Identifier
Object_Name
Object_Type
Present_Value
Status_Flags
Event_State
Out_Of_Service
Units
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Object_Name
Description
Out_Of_Service
Present_Value
Reliability
Min_Pres_Value
Max_Pres_Value
COV_Increment
Time_Delay
Notification_Class
High_Limit
Low_Limit
Deadband
Limit_Enable
Event_Enable
Notify_Type
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Description
Reliability
Min_Pres_Value
Max_Pres_Value
COV_Increment
Time_Delay
Notification _Class
High_Limit
Low_Limit
Deadband
Limit_Enable
Event_Enable
Acked_Transitions
Notify_Type
Event_Time_Stamps
Yes
Yes, only
user created
objects
Analog
Output
•
•
•
•
•
•
•
•
•
•
Object_Identifier
Object_Name
Object_Type
Present_Value
Status_Flags
Event_State
Out_Of_Service
Units
Priority_Array
Relinquish_Default
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Object_Name
Description
Out_Of_Service
Present_Value
Reliability
Min_Pres_Value
Max_Pres_Value
Relinquish_Default
COV_Increment
Time_Delay
Notification_Class
High_Limit
Low_Limit
Deadband
Limit_Enable
Event_Enable
Notify_Type
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Description
Reliability
Min_Pres-Value
Max_Pres_Value
COV_Increment
Time_Delay
Notification _Class
High_Limit
Low_Limit
Deadband
Limit_Enable
Event_Enable
Acked_Transitions
Notify_Type
Event_Time_Stamps
Yes
Yes, only
user created
objects
Analog
Value
•
•
•
•
•
•
•
•
Object_Identifier
Object_Name
Object_Type
Present_Value
Status_Flags
Event_State
Out_Of_Service
Units
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Object_Name
Description
Out_Of_Service
Present_Value
Reliability
Relinquish_Default
COV_Increment
Time_Delay
Notification_Class
High_Limit
Low_Limit
Deadband
Limit_Enable
Event_Enable
Notify_Type
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Description
Reliability
Priority_Array
Relinquish_Default
COV_Increment
Time_Delay
Notification_Class
High_Limit
Low_Limit
Deadband
Limit_Enable
Event_Enable
Acked_Transitions
Notify_Type
Event_Time_Stamps
Yes
Yes, only
user created
objects
Binary
Input
•
•
•
•
•
•
•
•
Object_Identifier
Object_Name
Object_Type
Present_Value
Status_Flags
Event_State
Out_Of_Service
Polarity
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Object_Name
Description
Out_Of_Service
Inactive_Text
Active_Text
Present_Value
Reliability
Change_Of_State_Count
Elapsed_Active_Time
Time_Delay
Notification_Class
Alarm_Value
Event_Enable
Acked_Transitions
Notify_Type
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Description
Inactive_Text
Active_Text
Change_Of_State_Time
Time_Of_State_Count_Reset
Elapsed_Active_Time
Time_Of_Active_Time_Reset
Time_Delay
Notification_Class
Alarm_Value
Event_Enable
Acked_Transitions
Notify_Type
Event_Time_Stamps
Reliability
Yes
Yes, only
user created
objects
19
Table 2.
Object
Type
Descriptions and configurations (continued)
Ability
to
Create
Ability to
Delete
Binary
Output
•
•
•
•
•
•
•
•
•
•
Object_Identifier
Object_Name
Object_Type
Present_Value
Status_Flags
Event_State
Out_Of_Service
Polarity
Priority_Array
Relinquish_Default
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Object_Name
Description
Out_Of_Service
Inactive_Text
Active_Text
Present_Value
Reliability
Elapsed_Active_Time
Minimum_On_Time
Minimum_Off_Time
Relinquish_Default
Time_Delay
Notification_Class
Event_Enable
Acked_Transitions
Notify_Type
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Description
Inactive_Text
Active_Text
Elapsed_Active_Time
Minimum_On_Time
Minimum_Off_Time
Time_Delay
Notification_Class
Feedback_Value
Event_Enable
Acked_Transitions
Notify_Type
Event_Time_Stamps
Reliability
Yes
Yes, only
user created
objects
Binary
Value
•
•
•
•
•
•
•
Object_Identifier
Object_Name
Object_Type
Present_Value
Status_Flags
Event_State
Out_Of_Service
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Object_Name
Description
Out_Of_Service
Inactive_Text
Active_Text
Present_Value
Reliability
Elapsed_Active_Time
Minimum_On_Time
Minimum_Off_Time
Relinquish_Default
Time_Delay
Notification_Class
Alarm_Value
Event_Enable
Acked_Transitions
Notify_Type
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Description
Inactive_Text
Active_Text
Elapsed_Active_Time
Priority_Array
Relinquish_Default
Minimum_On_Time
Minimum_Off_Time
Time_Delay
Notification_Class
Alarm_Value
Event_Enable
Acked_Transitions
Notify_Type
Event_Time_Stamps
Reliability
Yes
Yes, only
user created
objects
Location
Description
Max_Segments_Accepted
APDU_Segment_Timeout
Max_Master
Max_Info_Frames
Local_Time
Local_Date
Configuration_Files
Last_Restore_Time
Backup_Failure_Timeout
Active_COV_Subscriptions
None
None
Yes
Yes, only
user created
objects
• Polarity
Device
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Object_Identifier
Object_Name
Object_Type
System_Status
Vendor_Name
Vendor_Identifier
Model_Name
Firmware_Revision
Application_Software_Version
Protocol_Version
Protocol_Revision
Protocol_Services_Supported
Protocol_Object_Types_Supported
Object_List
Max_APDU_Length_Accepted
Segmentation_Supported
APDU_Timeout
Number_Of_APDU_Retries
Device_Address_Binding
Database_Revision
•
•
•
•
•
•
•
Object_Name
Location
Description
APDU_Segment_Timeout
APDU_Timeout
Number_Of_APDU_Retries
Backup_Failure_Timeout
•
•
•
•
•
•
•
•
•
•
•
•
Event
Enrollment
Object
•
•
•
•
•
•
•
•
•
•
•
•
Object_Identifier
Object_Name
Object_Type
Event_Type
Notify_Type
Event_Parameters
Object_Property_Reference
Event_State
Event_Enable
Acked_Transitions
Notification_Class
Event_Time_Stamps
•
•
•
•
•
•
Object_Name
Notify_Type
Event_Parameters
Object_Property_Reference
Event_Enable
Notification_Class
• None
20
Table 2.
Descriptions and configurations (continued)
Object
Type
Ability
to
Create
Ability to
Delete
Multistate
Input
•
•
•
•
•
•
•
•
Object_Identifier
Object_Name
Object_Type
Present_Value
Status_Flags
Event_State
Out_Of_Service
Number_Of_States
•
•
•
•
•
•
•
•
•
•
•
•
Object_Name
Description
State_Text
Out_Of_Service
Present_Value
Reliability
Time_Delay
Notification_Class
Alarm_Values
Fault_Values
Event_Enable
Notify_Type
•
•
•
•
•
•
•
•
•
•
State_Text
Reliability
Time_Delay
Notification_Class
Alarm_Values
Fault_Values
Event_Enable
Acked_Transitions
Notify_Type
Event_Time_Stamps
Yes
Yes, only
user created
objects
Multistate
Output
•
•
•
•
•
•
•
•
•
•
Object_Identifier
Object_Name
Object_Type
Present_Value
Status_Flags
Event_State
Out_Of_Service
Number_Of_States
Priority_Array
Relinquish Default
•
•
•
•
•
•
•
•
•
•
Object_Name
Description
State_Text
Out_Of_Service
Present_Value
Reliability
Time_Delay
Notification_Class
Event_Enable
Notify_Type
•
•
•
•
•
•
•
•
•
•
State_Text
Reliability
Relinquish_Default
Time_Delay
Notification_Class
Feedback_Values
Event_Enable
Acked_Transitions
Notify_Type
Event_Time_Stamps
Yes
Yes, only
user created
objects
Multistate
Value
•
•
•
•
•
•
•
•
Object_Identifier
Object_Name
Object_Type
Present_Value
Status_Flags
Event_State
Out_Of_Service
Number_Of_States
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Object_Name
Description
State_Text
Out_Of_Service
Present_Value
Reliability
Priority_Array
Relinquish_Default
Time_Delay
Notification_Class
Alarm_Values
Fault_Values
Event_Enable
Notify_Type
•
•
•
•
•
•
•
•
•
•
•
State_Text
Reliability
Relinquish_Default
Time_Delay
Notification_Class
Alarm_Values
Fault_Values
Event_Enable
Acked_Transitions
Notify_Type
Event_Time_Stamps
Yes
Yes, only
user created
objects
Notification
Class
•
•
•
•
•
•
•
Object_Identifier
Object_Name
Object_Type
Notification_Class
Priority
Ack_Required
Recipient_List
•
•
•
•
Object_Name
Priority
Ack_Required
Recipient_List
None
Yes
Yes, only
user created
objects
Trend
•
•
•
•
•
•
•
•
•
•
Object_Identifier
Object_Name
Object_Type
Log_Enable
Stop_When_Full
Buffer_Size
Log_Buffer
Record_Count
Total_Record_Count
Event_State
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Object_Name
Log_Enable
Start_Time
Stop_Time
Log_DeviceObjectProperty
Log_Interval
Stop_When_Full
Buffer_Size
Log_Buffer
Record_Count
Notification_Threshold
Notification_Class
Event_Enable
Notify_Type
•
•
•
•
•
•
•
•
•
•
•
•
•
Yes
Yes, only
user created
objects
Start_Time
Stop_Time
Log_DeviceObjectProperty
Log_Interval
Stop_When_Full
Buffer_Size
Notification_Threshold
Records_Since_Notification
Last_Notify_Record
Notification_Class
Event_Enable
Acked_Transitions
Event_Time_Stamps
(a)Properties written for Present_Value and Reliability only if Out_of_Service is TRUE.
21
BACnet Protocol
Data Link Layer Options
Supported
Option
Data Link Layer Description
ANSI/ATA 878.1, 2.5 Mb ARCNET (Clause 8)
ANSI/ATA 878.1, RS-485 ARCNET (Clause 8), Baud Rate(s)
BACnet IP, (Annex J)
BACnet IP, (Annex J), Foreign Device
ISO 8802-3, Ethernet (Clause 7)(10Base2, 10Base5, 10BaseT, Fiber)
LonTalk, (Clause 11), Medium
MS/TP Master (Clause 9), Baud Rate(s): 9600, 19200, 38400, 76800, and 115200 @1.5% Nominal Baud Rate
9
MS/TP Slave (Clause 9), Baud Rate(s)
Other
Point-to-Point, EIA 232 (Clause 10), Baud Rate(s): 9600, 19200, 38400
Point-to-Point, Modem (Clause 10), Baud Rate(s): 9600, 19200, 38400
Device Address Binding
Device Address Binding
Supported?
Static Device Binding Supported
9
Networking Options
Networking Descriptions
Supported
Option
Annex H, BACnet Tunneling
BACnet/IP Broadcast Management Device (BBMD)
Does the BBMD Support Registrations by Foreign Devices?
Router
22
Character Sets
Indicates support for multiple characters sets, but does not imply that all character sets are
supported simultaneously. Maximum supported string length is 64 bytes (any character set).
Character Set Descriptions
ANSI X3.4
Supported
9
IBM/Microsoft DBCS
ISO 10646 (UCS-4)
ISO 10646 (UCS2)
9
ISO 8859-1
9
JIS C 6226
23
Object Data Points and Diagnostic Data Points
For quick reference, the following tables are listed two different ways. Tables 2 through 9 are listed
by input/output type and sorted by object identifier. These tables provide the user with the units
type for each object type. Table 11, p. 34 and Table 12, p. 38 are sorted by object name and provide
a complete list of object names, types, values/ranges, and descriptions. Not all points are available
to the user. The available data points are defined during self-configuration and are dependent on
the type of equipment.
Table 3.
Analog Output
Object Identifier Object Name
Description
Refresh
Rate
(Sec.)
Units
Valid Range
Percent (98)
0 to 100
NA
Analog Output, 1
BAS supplied economizer
Economizer Minimum Position Setpoint BAS position minimum setpoint
value.
Analog Output, 2
Space Air Temperature Setpoint BAS
Base value to calculate setpoints
Degrees-Fahrenheit (64)
in occupied and standby modes.
50.0 to 90.0
NA
Analog Output, 4
Morning Warmup Setpoint BAS
BAS supplied temperature
setpoint used in morning
warmup mode.
50.0 to 90.0
NA
Analog Output, 5
Daytime Warmup Terminate Temperature
Setpoint BAS
BAS supplied daytime warmup
terminate temperature setpoint.
50.0 to 87.0
NA
Analog Output, 6
Discharge Air Cooling Setpoint BAS
BAS supplied discharge air
temperature cooling setpoint
value.
40.0 to 90.0
NA
Analog Output, 7
Discharge Air Heating Setpoint BAS
temperature heating setpoint
value.
40.0 to 180.0
NA
Analog Output, 8
Duct Static Air Pressure Setpoint BAS
BAS supplied duct static air
pressure setpoint value.
Inches-of-water (58)
0.70 to 4.30 (Ipak I)
0.70 to 5.10 (Ipak II)
NA
Analog Output, 9
Space Static Air Pressure Setpoint BAS
BAS supplied space static air
pressure setpoint value.
0.03 to 0.30
-0.02 to 0.30
(enhanced StatiTrac)
NA
Analog Output, 10
Space Static Air Pressure BAS
BAS supplied space static air
pressure sensor value.
-0.28 to 0.50
-0.67 to 0.67
(enhanced StatiTrac)
900
Analog Output, 11
BAS supplied space air
temperature sensor value.
-39.5 to 200.0
900
Analog Output, 12
-39.5 to 200.0
900
Analog Output, 13
BAS supplied duct static air
pressure sensor value.
0.0 to 5.0 (Ipak I)
0.0 to 7.9 (Ipak II)
900
Analog Output, 14
BAS supplied outdoor air
-39.5 to 200.0
900
Analog Output, 15
BAS supplied outdoor air
humidity sensor value.
Percent (98)
10.0 to 90.0
900
Analog Output, 16
Outdoor Air Minimum Flow Setpoint BAS
BAS supplied minimum outdoor
airflow setpoint.
Cubic-feet-per-minute (84)
0 to 60,000
NA
Analog Output, 17
Outdoor Air Flow BAS
BAS supplied outdoor airflow
sensor value.
0 to 65,000
900
Analog Output, 18
BAS supplied space CO2 sensor
value.
Parts-per-million
50 to 2,200
900
Analog Output, 19
Cool Capacity Enable Setpoint BAS
BAS supplied cooling demand
limit capacity setpoint value.
Percent (98)
0 to 100
NA
Analog Output, 20
Heat Capacity Enable Setpoint BAS
BAS supplied heating demand
limit capacity setpoint value.
Percent (98)
0 to 100
NA
Analog Output, 21
Space Dehumidification Setpoint BAS
BAS supplied space
dehumidification setpoint value.
Percent (98)
40 to 65
NA
Analog Output, 22
Discharge Air Dewpoint Setpoint BAS
dewpoint setpoint value.
45.0 to 75.0
NA
Analog Output, 23
Discharge Air Reheat Setpoint BAS
reheat setpoint value.
65.0 to 80.0
NA
24
Table 3.
Analog Output (continued)
Refresh
Rate
(Sec.)
Object Identifier Object Name
Description
Units
Valid Range
Analog Output, 25
Space Humidity BAS
BAS supplied space humidity
sensor value.
Percent (98)
10 to 90
900
Analog Output, 26
Space Humidification Setpoint BAS
BAS supplied space
humidification setpoint value.
Percent (98)
20 to 50
NA
Analog Output, 29
Occupied Temperature Offset BAS
Offset used to calculate setpoints
in occupied mode.
1.0 to 5.0
NA
Analog Output, 30
Standby Temperature Offset BAS
Offset value used to calculate
setpoints in standby mode.
1.0 to 10.0
NA
Analog Output, 31
Unoccupied Cooling Temperature Setpoint
BAS
Cooling temperature setpoint
used for control in unoccupied
mode.
52.0 to 88.0
NA
Analog Output, 32
Unoccupied Heating Temperature Setpoint
BAS
Heating temperature setpoint
used for control in unoccupied
mode.
50.0 to 90.0
NA
Table 4.
Analog Input
Object Identifier
Object Name
Description
Units (Listed Are Defaults)
Analog Input, 1
Cooling Capacity Status
Indicates the unit cooling capacity being utilized.
Percent (98)
Analog Input, 2
Heat Primary Capacity Status
Indicates the unit primary heating capacity being
utilized.
Percent (98)
Analog Input, 3
Heat Secondary Capacity Status
Indicates the unit secondary heating capacity being
utilized.
Percent (98)
Analog Input, 5
Reheat Capacity Status
Indicates the unit reheat heating capacity being
utilized.
Percent (98)
Analog Input, 6
Filter Runtime Hours
Indicates the number of hours air has flowed through
the filter.
Hours (71)
Percent (98)
Analog Input, 7
Supply Fan Speed Command
Indicates the unit commanded supply fan speed.
Analog Input, 8
Exhaust Fan Speed Command
Indicates the unit commanded exhaust fan speed.
Percent (98)
Analog Input, 9
Exhaust Damper Position Status
Indicates the unit exhaust damper position.
Percent (98)
Analog Input, 10
Return Fan Speed Command
Indicates the unit commanded return fan speed.
Percent (98)
Analog Input, 11
Outdoor Air Damper Position Status
Indicates the unit outdoor air damper position.
Percent (98)
Analog Input, 12
Waterside Economizer Valve Position Status
Indicates the unit waterside economizer valve position.
Percent (98)
Analog Input, 13
Frost Avoidance Temperature Setpoint
Indicates the frost coil avoidance temperature setpoint.
Analog Input, 14
Condenser Capacity Status
Indicates the unit condenser capacity being utilized.
Percent (98)
Analog Input, 15
Space Temperature Active
The space temperature currently used for unit control.
Analog Input, 16
Space Humidity Active
The space humidity value from a unit-mounted control.
Percent-relative-humidity (29)
Analog Input, 17
Space Enthalpy
The space enthalpy value from a unit-mounted control.
BTUs-per-pound (117)
Analog Input, 18
Outdoor Air Temperature Active
The outdoor air temperature currently used for unit
control.
Analog Input, 19
Outdoor Air Temperature Local
The outdoor air temperature value from a unitmounted sensor.
Analog Input, 20
Outdoor Air Humidity Active
The outdoor air humidity value used for unit control.
Outdoor Air Humidity Local
The outdoor air humidity value from a unit-mounted
sensor.
Analog Input, 22
Outdoor Air Dewpoint
The outdoor air dewpoint value being utilized by the
unit.
Degrees-Fahrenheit (64
Analog Input, 23
Outdoor Air Enthalpy
The outdoor air enthalpy value being utilized by the
unit.
Analog Input, 24
Discharge Air Temperature Active
The discharge air temperature currently used for unit
control.
Analog Input, 25
Mixed Air Temperature
The mixed air temperature value from a unit-mounted
sensor.
Return Air Temperature
The return air temperature value from a unit-mounted
sensor.
Analog Input, 21
Analog Input, 26
25
Table 4.
Analog Input (continued)
Object Identifier
Object Name
Description
Analog Input, 28
Duct Static Air Pressure Active
Duct static air pressure value currently being used for
unit control.
Analog Input, 29
Duct Static Air Pressure Local
Duct static air pressure value measured by a unitmounted sensor.
Analog Input, 30
Return Fan Air Pressure
Return fan air pressure value measured by a unitmounted sensor.
Analog Input, 31
Space Static Air Pressure Active
Space static air pressure value being used for unit
control.
Analog Input, 32
Space CO2 Concentration Active
Space CO2 concentration being used for unit control.
Parts-per-million (96)
Discharge Air Temperature Dewpoint
Discharge air temperature dewpoint being used by the
unit.
Analog Input, 34
Outdoor Air Flow Active
Outdoor airflow utilitzed by the unit.
Analog Input, 35
Condenser Water Entering Temperature
The temperature of the water entering the condenser.
Analog Input, 36
Evaporator Entering Temperature Circuit 1
Indicates the entering evaporator temperature for
circuit 1.
Analog Input, 37
Indicates the entering evaporator temperature for
circuit 2.
Analog Input, 38
Evaporator Leaving Temperature Circuit 1
Indicates the leaving evaporator temperature for
circuit 1
Analog Input, 39
circuit 2.
Analog Input, 40
circuit 3.
Analog Input, 41
circuit 4.
Analog Input, 42
Indicates the saturated condenser temperature for
Condensing Saturated Temperature Circuit 1
circuit 1.
Analog Input, 43
circuit 2.
Analog Input, 44
circuit 3.
Analog Input, 45
circuit 4.
Analog Input, 46
Condenser water leaving temperature value used for
Condenser Water Leaving Temperature Active
unit control.
Analog Input, 47
Condenser Water Leaving Temperature Local
Condenser water leaving temperature from a unitmounted sensor.
Analog Input, 48
Duct Static Air Pressure Setpoint Active
Duct static pressure setpoint value being used for unit
control.
Analog Input, 50
Space Air Temperature Setpoint Active
Space temperature setpoint value being used for unit
control.
Analog Input, 52
Discharge Air Temperature Setpoint Active
Discharge air temperature setpoint value being used
for unit control.
Analog Input, 54
Morning Warmup Air Temperature Setpoint
Active
The air temperature setpoint used during morning
warmup mode.
Analog Input, 55
Daytime Warmup Air Temperature Initiate
Setpoint Active
The air temperature setpoint used to start daytime
warmup mode.
Analog Input, 56
Economizer Minimum Position Setpoint Active
The minimum position value the economizer damper
will utilize.
Percent (98)
Analog Input, 57
Outdoor Air Minimum Flow Setpoint Active
The minimum outdoor airflow setpoint being utilized by
the unit.
Analog Input, 58
Dehumidification High Limit Setpoint
Humidity setpoint value that starts dehumidification
control.
Percent (98)
Analog Input, 60
Discharge Air Dewpoint Temperature
Setpoint
Humidity setpoint value used during dehumidification
control.
Analog Input, 61
Discharge Air Reheat Setpoint Active
Indicates the active supply air reheat temperature
setpoint.
Space Humidification Setpoint Active
Indicates the setpoint used during space humidification
control.
Percent (98)
Analog Input, 33
Analog Input, 62
26
Table 4.
Analog Input (continued)
Object Identifier
Object Name
Description
Analog Input, 64
Energy Recovery Exhaust Air Bypass Damper
Position
Energy recovery exhaust air bypass damper position.
Percent (98)
Analog Input, 65
Energy Recovery Leaving Exhaust Air
Temperature
Energy recovery leaving exhaust air temperature.
Analog Input, 66
Energy Recovery Outdoor Air Bypass Damper
Position
Energy recovery outdoor air bypass damper position.
Percent (98)
Analog Input, 67
Daytime Warmup Initiate Temperature
Setpoint Local
The local daytime warmup initiate temperature
setpoint.
Analog Input, 68
Daytime Warmup Terminate Temperature
Setpoint
Temperature setpoint that will exit daytime warmup
mode.
Analog Input, 69
Economizing Temperature Enable Setpoint
Temperature setpoint below which economizing can be
used.
Analog Input, 70
Economizing Enthalpy Enable Setpoint
Enthalpy setpoint below which economizing can be
used.
Analog Input, 71
Exhaust Enable Damper Position Setpoint
Exhaust air damper minimum position to enable
exhaust sequence.
Percent (98)
Analog Input, 74
Space Temperature Cooling Setpoint Input
Cooling temperature setpoint from space sensor
module.
Analog Input, 75
Space Temperature Heating Setpoint Input
Heating temperature setpoint from space sensor
module.
Analog Input, 76
Humidification Capacity Status
Indicates the unit humidification capacity being
utilized.
Percent (98)
Analog Input, 78
Space Temperature Setpoint Local
The local space temperature setpoint.
Analog Input, 79
Dehumidification Capacity Status
Indicates the unit dehumidification capacity being
utilized.
Percent (98)
Analog Input, 80
Cabinet Style
Describes the cabinet style of the unit.
NA
Analog Input, 81
Cool Type
Describes the cooling type installed in the unit.
NA
Analog Input, 82
Preheat Type
Describes the heating type installed in the unit.
NA
Analog Input, 83
Reheat Type
Describes the reheat type installed in the unit.
NA
Analog Input, 84
Space CO2 High Limit Setpoint
Indicates the high limit space CO2 setpoint for
ventilation.
Analog Input, 85
Space CO2 Low Limit Setpoint
Indicates the low limit space CO2 setpoint for
ventilation.
Analog Input, 86
Economizer Minimum Position Setpoint Local
Indicates the local economizer minimum position
setpoint.
Percent (98)
Analog Input, 87
Space Air Temperature Local
The space air temperature measured by a unitmounted sensor.
Analog Input, 88
Unit Energy Demand
Indicates the current heat/cool energy demand of the
unit.
Percent (98)
Analog Input, 89
Supply Fan Type
Describes the supply fan type installed in the unit.
NA
Exhaust or Return Fan Type
Describes the exhaust or return fan type installed in the
unit.
NA
Analog Input, 90
Table 5.
Analog Value
Object Identifier
Analog Value, 1
Object Name
Description
Units
Valid Range
Filter Runtime Hours Setpoint
The setpoint value
used by the filter
run hours
calculation.
Hours (71)
0 to 10,000
27
Table 6.
Multistate Output
BCI-I Object Identifier
Description
Object States
Economizer Airside Enable BAS
Command the state of the airside economizer system.
1 = Disabled
2 = Enabled
3 = Auto
Multi-State Output, 2
Emergency Override BAS
1
2
3
Command the unit into an emergency mode of operation.
4
5
6
Economizer Waterside Enable BAS
1 = Disabled
Command the state of the waterside economizer system. 2 = Enabled
3 = Auto
Occupancy Mode Request BAS
Command the unit into an occupancy mode.
1 = Occupied
2= Unoccupied
3 = Occupied Bypass
4 = Occupied Standby
Object Name
=
=
=
=
=
=
Normal
Pressurize
Depressurize
Purge
Shutdown
Fire
Application Mode Request BAS
Command the unit to a specific application mode.
1 = Auto
2 = Heat
3 = Morning Warmup
4 = Cool
5 = Night Purge
6 = Precool
7 = Off
8 = Test
9 = Emergency Heat
10 = Fan Only
11 = Free Cool
12 = Ice Making
13 = Max Heat
14 = Economy Mode
15 = Dehumidifying
16 = Calibrate
Condenser Water Flow BAS
Command the unit to utilize a remote water flow
indication.
1 = Flow
2 = No Flow
3 = Auto
Table 7.
Multistate Input
BCI-I Object
Identifier
Multi-State Input, 2
Object Name
Trane Unit Type
Description
Object States
General description of the equipment-type
classification.
1 = 1 Heat/1 Cool
2 = Heat Pump
3 = Blower Coil
4 = Unit Ventilator
5 = Fan Coil
6 = Rooftop
7 = Air Handler
8 = Vertical Self Contained
9 = Unitary
10 = VAV Box
11 = Fan Coil
Economizer Type
General description of the equipment
economizer system.
1 = None
2 = 2 Position Ventilation
3 = Modulation Economizer
4 = 2 Position Ventilation/Waterside Economizer
5 = Waterside Economizer
6 = Airside/Waterside Economizer
7 = TRAQ Damper
8 = Airside Economizer and TRAQ Damper/Sensor
9 = Waterside Economizer and TRAQ Damper/Sensor
10 = Airside/Waterside Economizer and TRAQ Damper/Sensor
Condenser Type
General description of the equipment
condenser system.
1
2
3
4
Indicates if the unit is in a ventilation
Ventilation Override Status
override mode of operation.
28
=
=
=
=
1=
2=
3=
4=
5=
6=
None
Air Cooled
Water Cooled
Evaporative
Inactive
Mode A Active
Mode B Active
Mode C Active
Mode D Active
Mode E Active
Table 7.
Multistate Input (continued)
BCI-I Object
Identifier
Object Name
Description
Object States
Economizer Decision
Method
Unit method to determine when the
economizer system is enabled.
1=
2=
3=
4=
Cooling Reset Type Status
Indicates the type of cooling reset.
1= None
2= Outdoor Air
3= Zone
Heating Reset Type Status Indicates the type of heating reset.
1= None
2= Outdoor Air
3= Zone
Absolute Temperature
Relative Temperature
Absolute Enthalpy
Comparative Enthalpy
Application Mode Status
Indicates the current application mode of
the equipment.
1 = Auto
2 = Heat
3 = Morning Warm-up
4 = Cool
5 = Night Purge
6 = Pre Cool
7 = Off
8 = Test
9 = Emergency Heat
10 = Fan Only
11 = Free Cool
12 = Ice-Making
13 = Max Heat
14 = Economy Mode
15 = Dehumidifying
16 = Calibrate
Occupancy Mode Status
Indicates the current occupancy mode of
the unit.
1
2
3
4
Unit Stop Source
Source of the stop command that turned off
the equipment.
1=
2=
3=
4=
5=
None
Emergency Stop
External Auto/Stop
Local HI
Remote HI
Cooling Setpoint Source
Indicates the source of the space cooling
setpoint.
1=
2=
3=
4=
5=
6=
RTM Zone Sensor
Night Setback Panel
Human Interface
GBAS 0-5V
BAS/Network
GBAS 0-10V
Heating Setpoint Source
Indicates the source of the space heating
setpoint.
1=
2=
3=
4=
5=
6=
RTM Zone Sensor
Night Setback Panel
Human Interface
GBAS 0-5V
BAS/Network
GBAS 0-10V
Timed Override Status
Timed override request or cancel from zone
sensor.
1 = Idle
2 = On
3 = Cancel
Cool Output 1
Indicates the commanded state of cooling
output 1.
1 = Off
2 = On
3 = Not Present
Cool Output 2
output 2.
1 = Off
2 = On
3 = Not Present
Cool Output 3
output 3.
1 = Off
2 = On
3 = Not Present
Cool Output 4
output 4.
1 = Off|
2 = On
3 = Not Present
Heat Output 1
Indicates the commanded state of heating
output 1.
1 = Off
2 = On
3 = Not Present
Heat Output 2
output 2.
1 = Off
2 = On
3 = Not Present
Heat Output 3
output 3.
1 = Off
2 = On
3 = Not Present
=
=
=
=
Occupied
Unoccupied
Occupied Bypass
Occupied Standby
29
Table 7.
Multistate Input (continued)
BCI-I Object
Identifier
Object Name
Description
Object States
Heat Output 4
output 4.
1 = Off
2 = On
3 = Not Present
Heat Output 5
output 5.
1 = Off
2 = On
3 = Not Present
Prefilter Status
Indicates the prefilter media state.
1 = Clean
2 = Dirty
3 = Not Present
Primary Filter Status
Indicates the primary filter media state.
1 = Clean
2 = Dirty
3 = Not Present
Final Filter Status
Indicates the final filter media state.
1 = Clean
2 = Dirty
3 = Not Present
1= Off
Supply Fan Proving Status Indicates the current state of the supply fan. 2= On
3= Not Present
Exhaust Fan Status
Indicates the commanded state of the
exhaust fan.
Exhaust Fan Proving
Status
1= Off
Indicates if the unit exhaust fan is off or on. 2= On
3= Not Present
1= Off
Return Fan Proving Status Indicates the current state of the return fan. 2= On
3= Not Present
Supply Fan Status
Indicates the state of the supply fan.
1 = Off
2 = On
3 = Not Present
Return Fan Status
Indicates the state of the return fan.
1 = Off
2 = On
3 = Not Present
Outdoor Air Damper
Status
Indicates the operating state of the outdoor
damper.
1 = At or Below Minimum Position
2 = Above Minimum Position
3 = Not Present
Economizer System Status
Indicates the operating state of the
waterside economizer system.
1 = Disabled
2 = Enabled
3 = Not Present
Table 8.
1 = Off
2 = On
3 = Not Present
Binary Output
Object Identifier
Relinquish
Default
Object Name
Description
Binary Output, 1
Command the unit to standaloneor BAS-controlled operation.
Inactive
Inactive = Standalone Control
Active = BAS Control
Binary Output, 5
Heat Lockout Command
Command the unit to prevent
heating operation.
Inactive
Inactive = Allow Heating
Active = Heating Locked Out
Binary Output, 6
Cool Lockout Command
Command the unit to prevent
cooling operation.
Inactive
Inactive = Allow Cooling
Active = Cooling Locked Out
Binary Output, 7
Economizer Minimum Position Command
Command the unit to the minimum
position operation.
Inactive
Inactive = Disabled
Active = Enabled
Binary Output, 8
Supply Fan Configuration Command
Command the unit supply fan to
cycling or continuous operation.
Inactive
Inactive = Auto
Active = On
Binary Output, 12
Heat or Reheat Enable Command
Enable the heating or reheating
system during dehumidification
mode.
Inactive
Inactive = Disabled
Active = Enabled
Binary Output, 13
Command the unit to reset the
accumulated filter run hours.
Inactive
Inactive = Accumulating
Active = Reset
Binary Output, 14
Diagnostic Reset Command
Command the unit to reset and
clear diagnostics.
Inactive
Inactive = Normal
Active = Reset
30
Object States
Table 8.
Binary Output
Object Identifier
Relinquish
Default
Object Name
Description
Binary Output, 15
Dehumidification Command
Command the operating state of
the dehumidification system.
Active
Inactive = Disabled
Active = Auto
Binary Output, 16
Humidification Command
Command the operating state of
the humidification system.
Active
Inactive = Disabled
Active = Auto
Object Name
Description
Object States
Binary Input, 1
System Control Status
Indicates the control system currently in
command of the unit.
Inactive = Standalone control
Active = BAS control
Binary Input, 2
Compressor Lockout Status
One or more compressors are locked out with
no diagnostic.
Inactive = Normal
Active = Locked Out
Binary Input, 3
Unit Status
Indicates the current state of the unit.
Inactive = Off
Active = On
Binary Input, 9
VAV Box Command
Indicates whether VAV boxes should be in
control or wide open.
Inactive = Auto
Active = Open
Binary Input, 10
Demand Limit Status
Indicates if the unit is in an energy-demand
limit mode
Inactive = Inactive
Active = Active
Binary Input, 11
Service Test Mode Status
Indicates if the unit is in service test mode.
Inactive = Inactive
Active = Active
Binary Input, 15
Supply Fan Configuration Status
Indicates the supply fan configuration.
Inactive = Cycling
Active = Continuous
Binary Input, 22
Economizer Airside Enable Status
Indicates the status of the airside economizer
system.
Inactive = Disabled
Active = Enabled
Binary Input, 23
Waterside Economizer Enable Status
Indicates the status of the waterside
economizer system.
Inactive = Disabled
Active = Enabled
Binary Input, 24
Condenser Water Pump Status
Indicates the status of the condenser water
system pump.
Inactive = Inactive
Active = Active
Binary Input, 25
Condenser Water Flow Status
Indicates the flow status of water in the
condenser system.
Inactive = No Flow
Active = Flow
Binary Input, 26
Energy Recovery Frost Avoidance Status
Status of the energy recovery system frost
protection function.
Inactive = Inactive
Active = Active
Binary Input, 27
Energy Recovery Status
Indicates the status of the energy recover
system.
Inactive = Inactive
Active = Active
Binary Input, 28
Energy Recovery Preheat Status
Indicates the status of the energy recovery
preheat function.
Inactive = Inactive
Active = Active
Binary Input, 161
Evaporator Frost Protection Circuit 1
Status
The status of evaporator frost protection
function for circuit 1.
Inactive = Inactive
Active = Active
Binary Input, 162
Status
Inactive = Inactive
Active = Active
Binary Input, 163
Status
Inactive = Inactive
Active = Active
Binary Input, 164
Status
Inactive = Inactive
Active = Active
Binary Input, 165
Alarm Relay Output Status
Indicates the state of the alarm relay on the
unit.
Inactive = De-energized
Active = Energized
Binary Input, 166
Diagnostic Stop Status
Indicates if the unit diagnostic has caused the
unit to shutdown.
Inactive = Inactive
Active = Active
Binary Input, 243
Condenser Water Drain Status
Indicates the status of the condenser water
drain
Inactive = Closed
Active = Open
Table 9.
Object States
Binary Input
Object Identifier
Table 10. Diagnostics, Binary Input
Object Identifier(a)
Object Name
Binary Input, 29
Diagnostic: RTM Zone Temp Sensor Failure
Binary Input, 30
Diagnostic: Supply Air Temp Sensor Fail
Diagnostic: RTM Aux Temp Sensor Failure
Diagnostic: SA Temp Sensor Fail
Diagnostic: SA Temp Sensor Fail
Binary Input, 31 (use Object
Identifier for RT or CSC)
Identifier for FAU)
Description
31
Table 10. Diagnostics, Binary Input (continued)
Object Name
Binary Input, 32
Diagnostic: OA Temperature Sensor Fail
Binary Input, 33
Diagnostic: Mode Input Failure
Description
Binary Input, 34
Diagnostic: Occ Zone Cool Setpoint Fail
Binary Input, 35
Diagnostic: Occ Zone Heat Setpoint Fail
Binary Input, 36
Diagnostic: Supply Air Press Sensor Fail
Binary Input, 37
Diagnostic: OA Humidity Sensor Failure
Binary Input, 38
Diagnostic: Emergency Stop
Binary Input, 39
Diagnostic: Supply Fan Failure
Binary Input, 40
Diagnostic: Exhaust/Return Fan Failure
Binary Input, 41
Diagnostic: Lvg Evap Temp Sensor Fail - Ckt1
Binary Input, 42
Binary Input, 43
Diagnostic: Low Pressure Ctl Open - Ckt1
Binary Input, 44
Binary Input, 45
Diagnostic: Cond Temp Sensor Fail - Ckt1
Binary Input, 46
Binary Input, 47
Diagnostic: Compressor Trip - Ckt1
Binary Input, 48
Binary Input, 49
Diagnostic: HEAT Aux Temp Sensor Fail
Binary Input, 50
Diagnostic: Low Air Temp Limit Trip
Binary Input, 51
Diagnostic: Heat Failure
Binary Input, 52
Diagnostic: Unocc Zone Cool Stpnt Fail
Binary Input, 53
Diagnostic: Unocc Zone Heat Stpnt Fail
Binary Input, 54
Diagnostic: SA Duct Press Setpoint Fail
Binary Input, 55
Diagnostic: Space Pressure Setpoint Fail
Binary Input, 56
Diagnostic: Space Pressure Sensor Fail
Binary Input, 57
Diagnostic: Return Air Temp Sensor Fail
Diagnostic: Return Air RH Sensor Failure
Diagnostic: Zone Humidity Sensor Failure
Identifier for FAU)
Binary Input, 59
Diagnostic: Auto - SA High Press Limit
Binary Input, 60
Diagnostic: Man - SA High Press Limit
Binary Input, 61
Diagnostic: SCM Communications Failure
Binary Input, 62
Diagnostic: MCM Communications Failure
Binary Input, 63
Diagnostic: HEAT Communications Failure
Binary Input, 64
Diagnostic: ECEM Communications Failure
Binary Input, 65
Diagnostic: GBAS 0-5 VDC Comm Failure
Binary Input, 66
Diagnostic: BACnet Module Comm Fail
Binary Input, 67
Diagnostic: BAS/Network Comm Fail
Binary Input, 68
Diagnostic: NSB Panel Communication Fail
Binary Input, 69
Diagnostic: RTM EEPROM Failure
Binary Input, 70
Diagnostic: Unit HI Communications Fail
Binary Input, 71
Diagnostic: VOM Communications Failure
Binary Input, 72
Diagnostic: Compressor Contact Fail-Ckt1
Binary Input, 73
Binary Input, 74
Diagnostic: SA Temp Cool Setpoint Fail
Binary Input, 75
Diagnostic: SA Temp Heat Setpoint Fail
Binary Input, 76
Diagnostic: Dirty Filter
Binary Input, 77
Diagnostic: NSB Zone Temp Sensor Fail
32
Object Name
Description
Binary Input, 78
Diagnostic: VOM Mode A Active
Binary Input, 79
Diagnostic: VOM Mode B Active
Binary Input, 80
Diagnostic: VOM Mode C Active
Binary Input, 81
Diagnostic: VOM Mode D Active
Binary Input, 82
Diagnostic: VOM Mode E Active
Binary Input, 83
Diagnostic: CO2 Sensor Failure
Binary Input, 84
Diagnostic: VCM Aux Temp Sensor Failure
Binary Input, 85
Diagnostic: Blocked Air Return
Diagnostic: Velocity Press Sensor Fail
Diagnostic: Vel Press Sensor (Rear)
Binary Input, 87
Diagnostic: VCM Communications Failure
Binary Input, 88
Diagnostic: WSM Communications Failure
Binary Input, 89
Diagnostic: Compressor Trip - Ckt 3
Identifier for CSC, FAU, I-pak I, RT)
Identifier for RT, I-pak II)
Binary Input, 90
Binary Input, 91
Diagnostic: Exh Fan VFD Bypass Enabled
Binary Input, 92
Binary Input, 93
Binary Input, 94
Diagnostic: Ent Cond Wtr Tmp Sensor Fail
Binary Input, 95
Diagnostic: WSM MA Temp Sensor Failure
Binary Input, 96
Diagnostic: Enter Water Temp Sensor Fail
Binary Input, 97
Diagnostic: Water Flow Failure
Binary Input, 98
Diagnostic: Supply Fan VFD Bypass Enable
Binary Input, 99
Diagnostic: High CO2 Level
Binary Input, 100
Binary Input, 101
Binary Input, 102
Binary Input, 103
Binary Input, 104
Diagnostic: Evap Temp Sensor Fail - Ckt4
Binary Input, 105
Binary Input, 106
Diagnostic: RTM Zone Humidity Sensor Fail
Binary Input, 107
Diagnostic: Ent Evap Temp Sensor Fail-Ckt 1
Binary Input, 108
Binary Input, 111
Diagnostic: Recovery Dirty Prefilter
Binary Input, 112
Diagnostic: Recovery Lvg RA Sensor Fail
Binary Input, 113
Diagnostic: Energy Recovery Wheel Fail
Binary Input, 114
Diagnostic: Cond Sump Max Level Fail
Binary Input, 115
Diagnostic: Cond Sump Min Level Fail
Binary Input, 116
Diagnostic: Cond Water Pump Fail (man)
Binary Input, 117
Diagnostic: Cond Water Pump Fail (auto)
Binary Input, 118
Diagnostic: Cond Water Temp Sensor Fail
Binary Input, 119
Diagnostic: Cond Sump Heater Fail (man)
Diagnostic: Cond Sump Heater Fail (man)
Binary Input, 120
Diagnostic: Reheat Head Press High
Diagnostic: SA Drying Setpoint Failure
Binary Input, 122
Diagnostic: Insufficient Airflow for Dehumid
Binary Input, 123
Diagnostic: SA Reheat Setpoint Failure
Identifier for RT)
Identifier for FAU)
33
Object Name
Description
Binary Input, 124
Diagnostic: Unocc Dehumid Setpoint Fail
Binary Input, 125
Diagnostic: Occ Dehumid Setpoint Failure
Binary Input, 126
Diagnostic: Unocc Humid Setpoint Fail
Binary Input, 127
Diagnostic: Occ Humid Setpoint Failure
Binary Input, 128
Diagnostic: MDM Communications Failure
Binary Input, 129
Diagnostic: Dirty Final Filter
Binary Input, 130
Diagnostic: Vel Press Sensor (Front) Fail
Binary Input, 131
Diagnostic: High Superheat - Ckt 1
Binary Input, 132
Diagnostic: Low Refrigerant Charge - Ckt 1
Binary Input, 133
Binary Input, 134
Binary Input, 139
Diagnostic: MPM Communications Failure
Binary Input, 140
Diagnostic: TPM Communications Failure
Binary Input, 141
Diagnostic: Return Plenum Press Sensor
Binary Input, 142
Diagnostic: Return Press High Limit (Man)
Binary Input, 143
Diagnostic: Return Press High Limit (Auto)
Binary Input, 144
Diagnostic: Cond Press Sensor Fail Ckt 2
Binary Input, 145
Binary Input, 146
Diagnostic: Invalid Unit Configuration
Binary Input, 147
Diagnostic: Maintenance Required
Binary Input, 148
Diagnostic: Unit Communications Failure
Binary Input, 149
Diagnostic: Unit Stopped at Local HI
Binary Input, 150
Diagnostic: Unit Stopped at Remote HI
Binary Input, 151
Diagnostic: RTM External Stop
Binary Input, 166
Diagnostic: Stop Status
Diagnostic: Stop Status
Binary Input, 233
Diagnostic: Sump Min Level Cycling (man)
(a) Object States: Inactive = normal and Active = foreign language specific
Table 11. All Object Types Sorted by Object Name (Refer to previous tables for detailed descriptions of objects)
Object Name
Binary Input, 165
Alarm Relay Output Status
Indicates the state of the alarm relay on the unit.
Application Mode Request BAS
Command the unit to a specific application mode.
Description
Application Mode Status
Indicates the current application mode of the equipment.
Analog Input, 80
Cabinet Style
Describes the cabinet style of the unit.
Binary Input, 2
Compressor Lockout Status
One or more compressors are locked out with no diagnostic.
Analog Input, 14
Condenser Capacity Status
Indicates the unit condenser capacity being utilized.
Condenser Type
General description of the equipment condenser system.
Binary Input, 243
Condenser Water Drain Status
Indicates the status of the condenser water drain
Analog Input, 35
Condenser Water Entering Temperature
The temperature of the water entering the condenser.
Condenser Water Flow BAS
Command the unit to utilize a remote water flow indication.
Binary Input, 25
Condenser Water Flow Status
Indicates the flow status of water in the condenser system.
Analog Input, 46
Condenser Water Leaving Temperature Active
Condenser water leaving temperature value used for unit control.
Analog Input, 47
Condenser Water Leaving Temperature Local
Condenser water leaving temperature from a unit-mounted sensor.
Binary Input, 24
Condenser Water Pump Status
Indicates the status of the condenser water system pump.
Analog Input, 42
Indicates the saturated condenser temperature for circuit 1.
34
Table 11. All Object Types Sorted by Object Name (Refer to previous tables for detailed descriptions of objects) (continued)
Object Name
Description
Analog Input, 43
Analog Input, 44
Analog Input, 45
Analog Output, 19
Cool Capacity Enable Setpoint BAS
BAS supplied cooling demand limit capacity setpoint value.
Binary Output, 6
Cool Lockout Command
Command the unit to prevent cooling operation.
Cool Output 1
Indicates the commanded state of cooling output 1.
Cool Output 2
Cool Output 3
Cool Output 4
Analog Input, 81
Cool Type
Describes the cooling type installed in the unit.
Analog Input, 1
Cooling Capacity Status
Indicates the unit cooling capacity being utilized.
Cooling Reset Type Status
Indicates the type of cooling reset.
Cooling Setpoint Source
Indicates the source of the space cooling setpoint.
Analog Input, 55
Daytime Warmup Air Temperature Initiate Setpoint
Active
The air temperature setpoint used to start daytime warmup mode.
Analog Input, 67
Daytime Warmup Initiate Temperature Setpoint Local
The local daytime warmup initiate temperature setpoint.
Analog Input, 68
Daytime Warmup Terminate Temperature Setpoint
Temperature setpoint that will exit daytime warmup mode.
Analog Output, 5
Daytime Warmup Terminate Temperature Setpoint BAS BAS supplied daytime warmup terminate temperature setpoint.
Analog Input, 79
Dehumidification Capacity Status
Indicates the unit dehumidification capacity being utilized.
Binary Output, 15
Dehumidification Command
Command the operating state of the dehumidification system.
Analog Input, 58
Dehumidification High Limit Setpoint
Humidity setpoint value that starts dehumidification control.
Binary Input, 10
Demand Limit Status
Indicates if the unit is in an energy-demand limit mode
Binary Output, 14
Diagnostic Reset Command
Command the unit to reset and clear diagnostics.
Binary Input, 166
Diagnostic Stop Status
Indicates if the unit diagnostic has caused the unit to shutdown.
Analog Output, 6
Discharge Air Cooling Setpoint BAS
BAS supplied discharge air temperature cooling setpoint value.
Analog Output, 22
Discharge Air Dewpoint Setpoint BAS
BAS supplied discharge air dewpoint setpoint value.
Analog Input, 60
Discharge Air Dewpoint Temperature Setpoint
Humidity setpoint value used during dehumidification control.
Analog Output, 7
Discharge Air Heating Setpoint BAS
BAS supplied discharge air temperature heating setpoint value.
Analog Input, 61
Discharge Air Reheat Setpoint Active
Indicates the active supply air reheat temperature setpoint.
Analog Output, 23
Discharge Air Reheat Setpoint BAS
BAS supplied discharge air reheat setpoint value.
Analog Input, 24
Discharge Air Temperature Active
The discharge air temperature currently used for unit control.
Analog Output, 12
BAS supplied discharge air temperature sensor value.
Analog Input, 33
Discharge Air Temperature Dewpoint
Discharge air temperature dewpoint being used by the unit.
Analog Input, 52
Discharge Air Temperature Setpoint Active
Discharge air temperature setpoint value being used for unit control.
Analog Input, 28
Duct Static Air Pressure Active
Duct static air pressure value currently being used for unit control.
Analog Output, 13
BAS supplied duct static air pressure sensor value.
Analog Input, 29
Duct Static Air Pressure Local
Duct static air pressure value measured by a unit-mounted sensor.
Analog Input, 48
Duct Static Air Pressure Setpoint Active
Duct static pressure setpoint value being used for unit control.
Analog Output, 8
Duct Static Air Pressure Setpoint BAS
BAS supplied duct static air pressure setpoint value.
Binary Input, 22
Economizer Airside Enable Status
Indicates the status of the airside economizer system.
Economizer Decision Method
Unit method to determine when the economizer system is enabled.
Binary Output, 7
Economizer Minimum Position Command
Command the unit to economizer minimum position operation.
Analog Input, 56
Economizer Minimum Position Setpoint Active
The minimum position value the economizer damper will utilize.
Analog Output, 1
Economizer Minimum Position Setpoint BAS
BAS supplied economizer position minimum setpoint value.
Analog Input, 86
Economizer Minimum Position Setpoint Local
Indicates the local economizer minimum position setpoint.
35
Object Name
Description
Economizer System Status
Indicates the operating state of the waterside economizer system.
Economizer Type
General description of the equipment economizer system.
Economizer Waterside Enable BAS
Command the state of the waterside economizer system.
Analog Input, 70
Economizing Enthalpy Enable Setpoint
Enthalpy setpoint below which economizing can be used.
Analog Input, 69
Economizing Temperature Enable Setpoint
Temperature setpoint below which economizing can be used.
Emergency Override BAS
Command the unit into an emergency mode of operation.
Analog Input, 64
Energy Recovery Exhaust Air Bypass Damper Position
Energy recovery exhaust air bypass damper position.
Binary Input, 26
Energy Recovery Frost Avoidance Status
Status of the energy recovery system frost protection function.
Analog Input, 65
Energy Recovery Leaving Exhaust Air Temperature
Energy recovery leaving exhaust air temperature.
Analog Input, 66
Energy Recovery Outdoor Air Bypass Damper Position
Energy recovery outdoor air bypass damper position.
Indicates the status of the energy recovery preheat function.
Binary Input, 28
Energy Recovery Preheat Status
Binary Input, 27
Energy Recovery Status
Indicates the status of the energy recover system.
Analog Input, 36
Indicates the entering evaporator temperature for circuit 1.
Analog Input, 37
Indicates the entering evaporator temperature for circuit 2.
Binary Input, 161
Evaporator Frost Protection Circuit 1 Status
The status of evaporator frost protection function for circuit 1.
Binary Input, 162
Binary Input, 163
Binary Input, 164
Analog Input, 38
Indicates the leaving evaporator temperature for circuit 1
Analog Input, 39
Indicates the leaving evaporator temperature for circuit 2.
Analog Input, 40
Analog Input, 41
Analog Input, 9
Exhaust Damper Position Status
Indicates the unit exhaust damper position.
Analog Input, 71
Exhaust Enable Damper Position Setpoint
Exhaust air damper minimum position to enable exhaust sequence.
Exhaust Fan Proving Status
Indicates if the unit exhaust fan is off or on.
Analog Input, 8
Exhaust Fan Speed Command
Indicates the unit commanded exhaust fan speed.
Exhaust Fan Status
Indicates the commanded state of the exhaust fan.
Analog Input, 90
Exhaust or Return Fan Type
Describes the exhaust or return fan type installed in the unit.
Analog Input, 6
Filter Runtime Hours
Indicates the number of hours air has flowed through the filter.
Analog Value, 1
Filter Runtime Hours Setpoint
The setpoint value used by the filter run hours calculation.
Binary Output, 13
Command the unit to reset the accumulated filter run hours.
Final Filter Status
Indicates the final filter media state.
Analog Input, 13
Frost Avoidance Temperature Setpoint
Indicates the frost coil avoidance temperature setpoint.
Analog Output, 20
Heat Capacity Enable Setpoint BAS
BAS supplied heating demand limit capacity setpoint value.
Binary Output, 5
Heat Lockout Command
Command the unit to prevent heating operation.
Binary Output, 12
Heat or Reheat Enable Command
Enable the heating or reheating system during dehumidification mode.
Indicates the commanded state of heating output 1.
Heat Output 1
Heat Output 2
Heat Output 3
Heat Output 4
Heat Output 5
Analog Input, 2
Heat Primary Capacity Status
Indicates the unit primary heating capacity being utilized.
Analog Input, 3
Heat Secondary Capacity Status
Indicates the unit secondary heating capacity being utilized.
Heating Reset Type Status
Indicates the type of heating reset.
Heating Setpoint Source
Indicates the source of the space heating setpoint.
Analog Input, 76
Humidification Capacity Status
Indicates the unit humidification capacity being utilized.
36
Object Name
Description
Binary Output, 16
Humidification Command
Command the operating state of the humidification system.
NC 3
HVAC-Advisory
HVAC-Advisory
NC 1
HVAC-Critical
HVAC-Critical
NC 4
HVAC-Information
HVAC-Information
NC 2
HVAC-Service Required
HVAC-Service Required
Analog Input, 25
Mixed Air Temperature
The mixed air temperature value from a unit-mounted sensor.
Analog Input, 54
Morning Warmup Air Temperature Setpoint Active
The air temperature setpoint used during morning warmup mode.
Analog Output, 4
Morning Warmup Setpoint BAS
BAS supplied temperature setpoint used in morning warmup mode.
Occupancy Mode Request BAS
Command the unit into an occupancy mode.
Occupancy Mode Status
Indicates the current occupancy mode of the unit.
Analog Output, 29
Occupied Temperature Offset BAS
Offset used to calculate setpoints in occupied mode.
Analog Input, 11
Outdoor Air Damper Position Status
Indicates the unit outdoor air damper position.
Outdoor Air Damper Status
Indicates the operating state of the outdoor damper.
Analog Input, 22
Outdoor Air Dewpoint
The outdoor air dewpoint value being utilized by the unit.
Analog Input, 23
Outdoor Air Enthalpy
The outdoor air enthalpy value being utilized by the unit.
Analog Input, 34
Outdoor Air Flow Active
Outdoor airflow utilized by the unit.
Analog Output, 17
Outdoor Air Flow BAS
BAS supplied outdoor airflow sensor value.
Analog Input, 20
Outdoor Air Humidity Active
The outdoor air humidity value used for unit control.
Analog Output, 15
BAS supplied outdoor air humidity sensor value.
Analog Input, 21
Outdoor Air Humidity Local
The outdoor air humidity value from a unit-mounted sensor.
Analog Input, 57
Outdoor Air Minimum Flow Setpoint Active
The minimum outdoor airflow setpoint being utilized by the unit.
Analog Output, 16
Outdoor Air Minimum Flow Setpoint BAS
BAS supplied minimum outdoor airflow setpoint.
Analog Input, 18
Outdoor Air Temperature Active
The outdoor air temperature currently used for unit control.
Analog Output, 14
BAS supplied outdoor air temperature sensor value.
Analog Input, 19
Outdoor Air Temperature Local
The outdoor air temperature value from a unit-mounted sensor.
Prefilter Status
Indicates the prefilter media state.
Analog Input, 82
Preheat Type
Describes the heating type installed in the unit.
Primary Filter Status
Indicates the primary filter media state.
Analog Input, 5
Reheat Capacity Status
Indicates the unit reheat heating capacity being utilized.
Analog Input, 83
Reheat Type
Describes the reheat type installed in the unit.
Analog Input, 26
Return Air Temperature
The return air temperature value from a unit-mounted sensor.
Analog Input, 30
Return Fan Air Pressure
Return fan air pressure value measured by a unit-mounted sensor.
Return Fan Proving Status
Indicates the current state of the return fan.
Analog Input, 10
Return Fan Speed Command
Indicates the unit commanded return fan speed.
Return Fan Status
Indicates the state of the return fan.
Binary Input, 11
Service Test Mode Status
Indicates if the unit is in service test mode.
Analog Output, 11
BAS supplied space air temperature sensor value.
Analog Input, 87
Space Air Temperature Local
The space air temperature measured by a unit-mounted sensor.
Analog Input, 50
Space Air Temperature Setpoint Active
Space temperature setpoint value being used for unit control.
Analog Output, 2
Space Air Temperature Setpoint BAS
Base value to calculate setpoints in occupied and standby modes.
Analog Input, 32
Space CO2 Concentration Active
Space CO2 concentration being used for unit control.
Analog Output, 18
BAS supplied space CO2 sensor value.
Analog Input, 84
Space CO2 High Limit Setpoint
Indicates the high limit space CO2 setpoint for ventilation.
Analog Input, 85
Space CO2 Low Limit Setpoint
Indicates the low limit space CO2 setpoint for ventilation.
Analog Output, 21
Space Dehumidification Setpoint BAS
BAS supplied space dehumidification setpoint value.
Analog Input, 17
Space Enthalpy
The space enthalpy value from a unit-mounted control.
37
Object Name
Description
Analog Input, 62
Space Humidification Setpoint Active
Indicates the setpoint used during space humidification control.
Analog Output, 26
Space Humidification Setpoint BAS
BAS supplied space humidification setpoint value.
Analog Input, 16
Space Humidity Active
The space humidity value from a unit-mounted control.
Analog Output, 25
Space Humidity BAS
BAS supplied space humidity sensor value.
Analog Input, 31
Space Static Air Pressure Active
Space static air pressure value being used for unit control.
Analog Output, 10
Space Static Air Pressure BAS
BAS supplied space static air pressure sensor value.
Analog Output, 9
Space Static Air Pressure Setpoint BAS
BAS supplied space static air pressure setpoint value.
Analog Input, 15
Space Temperature Active
The space temperature currently used for unit control.
Analog Input, 74
Space Temperature Cooling Setpoint Input
Cooling temperature setpoint from space sensor module.
Analog Input, 75
Space Temperature Heating Setpoint Input
Heating temperature setpoint from space sensor module.
Analog Input, 78
Space Temperature Setpoint Local
The local space temperature setpoint.
Analog Output, 30
Standby Temperature Offset BAS
Offset value used to calculate setpoints in standby mode.
Binary Output, 8
Supply Fan Configuration Command
Command the unit supply fan to cycling or continuous operation.
Binary Input, 15
Supply Fan Configuration Status
Indicates the supply fan configuration.
Supply Fan Proving Status
Indicates the current state of the supply fan.
Analog Input, 7
Supply Fan Speed Command
Indicates the unit commanded supply fan speed.
Supply Fan Status
Indicates the state of the supply fan.
Analog Input, 89
Supply Fan Type
Describes the supply fan type installed in the unit.
Binary Output, 1
Command the unit to standalone- or BAS-controlled operation.
Binary Input, 1
System Control Status
Indicates the control system currently in command of the unit.
Timed Override Status
Timed override request or cancel from zone sensor.
Trane Unit Type
General description of the equipment-type classification.
Analog Input, 88
Unit Energy Demand
Indicates the current heat/cool energy demand of the unit.
Binary Input, 3
Unit Status
Indicates the current state of the unit.
Unit Stop Source
Source of the stop command that turned off the equipment.
Analog Output, 31
Unoccupied Cooling Temperature Setpoint BAS
Cooling temperature setpoint used for control in unoccupied mode.
Analog Output, 32
Unoccupied Heating Temperature Setpoint BAS
Heating temperature setpoint used for control in unoccupied mode.
Binary Input, 9
VAV Box Command
Indicates whether VAV boxes should be in control or wide open.
Ventilation Override Status
Indicates if the unit is in a ventilation override mode of operation.
Binary Input, 23
Waterside Economizer Enable Status
Indicates the status of the waterside economizer system.
Analog Input, 12
Waterside Economizer Valve Position Status
Indicates the unit waterside economizer valve position.
(a) AI=Analog Input, AO=Analog Output, AV=Analog Value, BI=Binary Input, BO=Binary Output, MI=Multistate Input, MO=Multistate Output
Table 12. Diagnostic Objects Sorted by Object Name
Object Identifier(a) Object Name
Value/Range
Description
BI 59
0 = inactive
1 = active
BI 66
0 = inactive
1 = active
38
Table 12. Diagnostic Objects Sorted by Object Name (continued)
Value/Range
Description
BI 67
0 = inactive
1 = active
BI 85
0 = inactive
1 = active
BI 83
0 = inactive
1 = active
BI 72
0 = inactive
1 = active
BI 73
0 = inactive
1 = active
BI 103
0 = inactive
1 = active
BI 102
0 = inactive
1 = active
BI 89
0 = inactive
1 = active
BI 90
0 = inactive
1 = active
BI 47
0 = inactive
1 = active
BI 48
0 = inactive
1 = active
BI 114
0 = inactive
1 = active
BI 115
0 = inactive
1 = active
BI 45
0 = inactive
1 = active
BI 46
0 = inactive
1 = active
BI 92
0 = inactive
1 = active
BI 93
0 = inactive
1 = active
BI 117
0 = inactive
1 = active
BI 116
0 = inactive
1 = active
BI 118
0 = inactive
1 = active
BI 76
0 = inactive
1 = active
BI 129
0 = inactive
1 = active
BI 64
0 = inactive
1 = active
BI 38
0 = inactive
1 = active
BI 113
0 = inactive
1 = active
BI 94
0 = inactive
1 = active
BI 107
0 = inactive
1 = active
BI 108
0 = inactive
1 = active
BI 109
0 = inactive
1 = active
39
Value/Range
Description
BI 110
0 = inactive
1 = active
BI 96
0 = inactive
1 = active
BI 105
0 = inactive
1 = active
BI 104
0 = inactive
1 = active
BI 91
0 = inactive
1 = active
BI 40
0 = inactive
1 = active
BI 120
0 = inactive
1 = active
BI 65
0 = inactive
1 = active
BI 49
0 = inactive
1 = active
BI 63
0 = inactive
1 = active
BI 51
0 = inactive
1 = active
BI 99
0 = inactive
1 = active
BI 131
0 = inactive
1 = active
BI 133
0 = inactive
1 = active
BI 122
0 = inactive
1 = active
BI 146
0 = inactive
1 = active
BI 50
0 = inactive
1 = active
BI 43
0 = inactive
1 = active
BI 44
0 = inactive
1 = active
BI 101
0 = inactive
1 = active
BI 100
0 = inactive
1 = active
BI 132
0 = inactive
1 = active
BI 134
0 = inactive
1 = active
BI 41
0 = inactive
1 = active
BI 42
0 = inactive
1 = active
BI 147
0 = inactive
1 = active
BI 60
0 = inactive
1 = active
BI 62
0 = inactive
1 = active
BI 128
0 = inactive
1 = active
40
Value/Range
Description
BI 33
0 = inactive
1 = active
BI 139
0 = inactive
1 = active
BI 68
0 = inactive
1 = active
BI 77
0 = inactive
1 = active
BI 37
0 = inactive
1 = active
BI 32
0 = inactive
1 = active
BI 125
0 = inactive
1 = active
BI 127
0 = inactive
1 = active
BI 34
0 = inactive
1 = active
BI 35
0 = inactive
1 = active
BI 111
0 = inactive
1 = active
BI 112
0 = inactive
1 = active
0 = inactive
1 = active
BI 119
Diagnostic: Reheat Sat Cond Temp Sensor
0 = inactive
1 = active
Diagnostic: Reheat Sat Cond Temp Sensor
BI 58 (use Object
0 = inactive
1 = active
BI 57
0 = inactive
1 = active
BI 141
0 = inactive
1 = active
BI 143
0 = inactive
1 = active
BI 142
0 = inactive
1 = active
BI 31 (use Object
Identifier for RT CSC)
0 = inactive
1 = active
BI 69
0 = inactive
1 = active
BI 15
0 = inactive
1 = active
BI 151
0 = inactive
1 = active
BI 106
0 = inactive
1 = active
BI 29
0 = inactive
1 = active
0 = inactive
1 = active
Diagnostic: SA Drying Temp Sensor Fail
0 = inactive
1 = active
Diagnostic: SA Drying Temp Sensor Fail
BI 54
0 = inactive
1 = active
BI 123
0 = inactive
1 = active
BI 121 (use Object
Identifier for RT)
BI 121 (use Object
Identifier for FAU)
B1 31 (use Object
Identifier for FAU)
41
Value/Range
Description
BI 74
0 = inactive
1 = active
BI 75
0 = inactive
1 = active
BI 61
0 = inactive
1 = active
BI 56
0 = inactive
1 = active
BI 55
0 = inactive
1 = active
BI 233
0 = inactive
1 = active
BI 36
0 = inactive
1 = active
BI 30
0 = inactive
1 = active
BI 39
0 = inactive
1 = active
BI 98
0 = inactive
1 = active
BI 140
0 = inactive
1 = active
BI 148
0 = inactive
1 = active
BI 70
0 = inactive
1 = active
BI 149
0 = inactive
1 = active
BI 150
0 = inactive
1 = active
BI 124
0 = inactive
1 = active
BI 126
0 = inactive
1 = active
BI 52
0 = inactive
1 = active
BI 53
0 = inactive
1 = active
BI 84
0 = inactive
1 = active
BI 87
0 = inactive
1 = active
BI 130
0 = inactive
1 = active
BI 86 (use Object
Identifier for Ipak II-RT)
0 = inactive
1 = active
BI 86 (use Object
Identifier for Ipak I-RT,
CSC, FAU)
0 = inactive
1 = active
BI 71
0 = inactive
1 = active
BI 78
0 = inactive
1 = active
BI 79
0 = inactive
1 = active
BI 80
0 = inactive
1 = active
BI 81
0 = inactive
1 = active
42
Value/Range
Description
BI 82
0 = inactive
1 = active
BI 97
0 = inactive
1 = active
BI 88
0 = inactive
1 = active
BI 95
0 = inactive
1 = active
BI 58 (use Object
Identifier for FAU)
0 = inactive
1 = active
(a) BI=Binary Input
43
Additional Resources
Additional Resources
Use the following documents and links as additional resources:
•
Product support online:
• www.bacnet.org
• www.bacnetassociation.org
• www.ashrae.org
• Tracer TU Help online
•
Tracer™ TU Service Tool Getting Started Guide (TTU-SVN02) (X39641083)
•
Tracer TU Service Tool for Water-cooled CenTraVac Chillers with Tracer AdaptiView Control
Programming Guide (current version of CTV-SVP02)
Note: For further assistance, contact your local Trane sales office.
44
Glossary
A
ASHRAE
See American Society of Heating, Refrigeration, and Airconditioning Engineers
American Society of Heating, Refrigeration, and Airconditioning Engineers
An international organization of 50,000 persons with
chapters throughout the world. The Society is organized
for the sole purpose of advancing the arts and sciences of
heating, ventilation, air conditioning and refrigeration. It
benefits the public with its research, standards writing,
continuing education, and publications.
advocates BACnet protocol for use in system-level control
devices.
device
A device is a standard BACnet object as defined by
ASHRAE Standard 135-2004.The Tracer UC800 contains
the BACnet object.
Device ID
The Device ID is used to uniquely identify each BACnet
Device and it can be in the range of 0 to 4194302. There
cannot be more than one device using the same Device
ID. Each of the sample applications operate as a device
and requires its own device id which defaults to zero.
B
I
BACnet™
See Building Automation Control network
interoperability
The ability to integrate equipment from different vendors
into a comprehensive automation and control system. In
addition, digital communications between products
designed independently, but designed to the same
communication standard.
BACnet interoperability building blocks
A block of BACnet application services that tells vendors
what BACnet services must be implemented to provide
specific device functionality. The BIBBs are grouped
together into BACnet device profiles.
P
BACnet object
An abstract representation of the physical point or points
where data is input from or output to an I/O device. Each
object may have several BACnet properties that describe
the status of that object.
protocol
A set of rules (language) that governs the exchange of
data over a digital communications system.
baud rate
The number of signaling elements that occur each second
during electronic data transmission. At slow speeds, baud
indicates the number of bits per second that are
transmitted. For example, 500 baud means that 500 bits
are transmitted each second (abbreviated 500 bps). At
higher speeds, multiple bits may be encoded with each
electrical change. For example, 4,800 baud may allow
9,600 bits to be sent each second. Data transmission
rates at high speeds are generally expressed in bits per
second (bps) rather than baud. For example, a 9,600 bps
modem may operate at only 2,400 baud.
stand-alone operation
Equipment is running in a stand-alone mode when all
control is provided by the equipment's electronic control
system. The system controls the building environment to
a local set of configuration and setpoint values. It monitors
the environmental conditions via sensors that are
physically wired to the unit's control system.
S
BIBB
See BACnet interoperability building blocks
Building Automation Control network (BACnet and
ANSI/ASHRAE Standard 135-2004)
An interoperable protocol developed specifically for the
building controls industry. The American National
Standards Institute named it as a standard and Trane
45
www.trane.com
For more information, contact your local Trane
office or e-mail us at [email protected]
Literature Order Number
ACC-SVP01B-EN
Date
September 2009
Supersedes
ACC-SVP01A-EN
Trane has a policy of continuous product and product data improvement and reserves the right to
change design and specifications without notice.

BACnet Communication Interface (BCI-I)

Transcription

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